Abstract: A fixing clip for fixing a member to a body panel includes a bushing and a lock pin. The bushing includes a head, a leg and paired engagement hooks. Each engagement hook includes a head-side engagement portion and a leg tip-side engagement portion located closer to a tip of the leg than the head-side engagement portion. Each engagement hook includes a rib extending from the tip-side engagement portion toward the head. When the leg tip-side engagement portion is brought into engagement with the body panel, since the fixing clip has been largely inclined relative to the body panel, a bending moment acting on the leg is decreased so that the leg is unlikely to be broken at a root of the leg. As a result, a durability of the fixing clip having two steps of engagement portions is improved compared to a conventional fixing clip having a single engagement portion.

Abstract: A spacer fabric may include a hinge layer, a top layer, and an intermediate layer. The hinge layer may include a first tensile strength and at least one perforation. The top layer may include a second tensile strength. The intermediate layer may include a third tensile strength, and may be arranged between the hinge layer and the top layer. The first tensile strength may be higher than the second tensile strength, and the first tensile strength may be higher than the third tensile strength.

Abstract: The invention relates to a structure for receiving an inflatable airbag 25 which is located in a housing of an airbag module 21, with a decorative cover 1 for covering a component of a vehicle seat 4, wherein the decorative cover 1 has a front decorative cover area 2 and a rear decorative cover area 3, wherein the front decorative cover area 2 and the rear decorative cover area 3 are connected to each other in the area of their edge sections via a first connection 5 which can be released when the airbag 25 is deployed, wherein the front decorative cover area 2 has a first outer surface 6 and a first inner surface 7 and the rear decorative cover area 3 has a second outer surface 8 and a second inner surface 9, with a first support bar 10 made of a rigid material, which has at least one through hole 15 for receiving a connection pin 24 which is formed on the housing of the airbag module 21, and which has fastening means for fastening a first protective sheet 16, wherein the first support bar 10 has a front area

Abstract: An airbag of an airbag device for a front passenger seat includes a passenger-side wall, a circumferential wall, a gas inlet port disposed in a vicinity of the front end of the airbag as deployed, a bottom pocket that is recessed upward from a lower region of the circumferential wall in such a manner as to be continuous with the lower region, and a tether that is disposed generally along a front and rear direction inside the airbag and connects the passenger-side wall and a vicinity of the gas inlet port. The bottom pocket is formed into a pouch like contour by joining outer circumferential edges of left and right bottom pocket constituent regions that extend from the lower region of the circumferential wall. The upper end region of the bottom pocket is joined to the tether.

Abstract: An apparatus (10) for helping to protect an occupant (28) of a vehicle (12) includes an inflatable vehicle occupant protection device (14) configured to be inflated and deployed between a side structure (16) of the vehicle and the vehicle occupant. A deployment sleeve (50) encircles a portion of the protection device. The deployment sleeve (50) includes a rupturable tear seam (54) that absorbs the initial break-out forces of the protection device (14) during the initial stages of inflation and deployment. The tear seam (54) is adapted to rupture after the deployment sleeve (50) absorbs the break-out forces and release the protection device (14) to inflate and deploy to a fully inflated and deployed condition.

Abstract: A curtain airbag for a vehicle has a main chamber shaped in the position being mounted on the vehicle, in the inflated state covering an inner side structure of the vehicle. The curtain airbag has an additional chamber which, in the mounting position, is located at the in driving direction of the vehicle front portion of the main chamber, and deploys in the direction of the interior of the vehicle when the curtain airbag is inflated. The additional chamber is attached to the main chamber so as to be positioned in the inflated state between the front portion of the main chamber and an occupant to be restrained by the curtain airbag.

Abstract: An airbag of an airbag device includes a connection port to be joined with an inflator and a flexible reinforcing sheet disposed inside the connection port. The reinforcing sheet includes a first cover region and a second cover region each of which wraps the leading end of the inflator and has an opening for providing gas communication with a main body of the airbag. The first cover region has a double-folded configuration that is doubled on a crease which crosses an axial direction of the inflator while the second cover region has a double-folded configuration that is doubled on a crease extending in parallel to the axial direction of the inflator. The first cover region and second cover region are arranged in such an overlapped fashion that the crease of the first cover region continues to the crease of the second cover region.

Abstract: A belt retractor (10) is provided with a retractor shaft (12) and a device (26) for determining the rotational speed and/or the angle of rotation of the retractor shaft (12), with a rotating magnetic element (18), a stationary magnetic field sensor (24) and a stationary element guiding the magnetic flux (20) arranged between the rotating magnetic element (18) and the magnetic field sensor (24).

Abstract: A method is described including receiving sensory data, determining an indication of initial user impairment based on the sensory data, providing one or more games to the user to determine a level of user impairment, calculating a game score based on user responses to the one or more games and providing an indication of impairment upon a determination that the game score indicates user impairment.

Abstract: The invention relates to a method for operating an internal combustion engine (14) of a motor vehicle (10), in that the internal combustion engine (14) is started using a remote start unit (18) for wireless reception of a remote start signal (R) and afterwards is monitored by a shutdown unit (36) to determine whether a shutdown condition is fulfilled. When appropriate, the internal combustion engine (14) is shutdown again. A radio key device (26) of the motor vehicle (10) is designed to detect a radio key presence in a passenger compartment (28) of the motor vehicle (10) using a key scan and to signal a radio key presence by means of a key presence signal (A). The problem addressed by the invention is to adapt the subsequent shutdown of the internal combustion engine (14) more flexibly to the position of the driver following a remote start. The shutdown condition comprises for this purpose that the key presence signal (A) must have been inactive for a predefined minimum time period.

Abstract: The apparatus is a trapped key safety interlock device for use with a coupling that comprises a body provided with a face seal, a rim on one side and a projecting spur on the diametrically opposite side. The safety device includes a coupling part (201) which is complimentary to the said coupling (102) and which comprises a body portion having a rim portion (207) on one side for engagement with the spur of the said coupling and having a spur portion (206) on the diametrically opposite side for engagement with the rim of the said coupling (102). The rim portion accommodates a release mechanism (16, 18) for selectively enabling and disabling a key retention mechanism within the device. The key retention mechanism has a key retention condition and a key releasable condition, wherein the release mechanism comprises a primary release mechanism (16) and a secondary latching mechanism (18) resisting movement of the primary release mechanism until it is actuated itself.

Abstract: A vehicle system comprises an onboard apparatus that is mounted to a vehicle, and a portable device. The vehicle system controls the vehicle according to a result of collation using wireless communication in which a signal is transmitted and received on electric wave, between the onboard apparatus and the portable device. The onboard apparatus includes a vehicle-side transmission processor that transmits a first signal which specifies signal intensity information and, following transmission of the first signal, transmits a second signal having a signal intensity, the signal intensity information being information on the signal intensity of the second signal. The portable device includes a portable device-side reception antenna that receives a signal transmitted from the vehicle-side transmission antenna, a signal intensity measurement portion, and a reply determiner that determines whether a replay is performed to the onboard apparatus for the collation.

Abstract: The invention relates to an end cap arrangement, more particularly for a wiper blade (12a; 12b), comprising an end cap main part (14a; 14b) that can be fixedly connected to a main component (10a; 10b) of a wiper blade (12a; 12b). It is proposed that the end cap arrangement comprise at least an end cap spoiler element (16a; 16b) which is designed so that in an installed condition an installation opening (18a; 18b) is left free for a wiper rubber (20a; 20b).

Abstract: A novel wiper strip is presented having a wiper lip made of a first material, a base strip, a neck connecting the wiper lip to the base strip, and a wiper lip insert made of a second material. The second material may be harder than the first material. Additionally, the wiper lip insert may further include a lip portion that is embedded in the wiper lip. A wiper blade having a mounting base, a force distribution structure and a wiper strip consistent with the description above is also presented.

Abstract: A wiper blade with a support assembly has a plurality of levers and housed by covers, which enhances the universality of the required parts and reduces the number of the required parts and thus, the cost of fabrication, while allowing the covers to follow the round contour of a surface to be wiped. The wiper blade includes a primary cover and secondary covers pivotally connected to the primary cover. Each of the secondary covers include a lever guide section through which a yoke lever is slidably movable in a direction longitudinally of the wiper blade.

Abstract: A portable undercarriage washer for vehicles includes a spray manifold having a feed line with a proximal end and a distal end, a spray tube coupled with the distal end of the feed lines, and a plurality of spaced spray nozzles connected with spaced openings on the spray tube. A protective cover overlies the spray manifold and the spaced spray nozzles. The protective cover has a top surface, a bottom surface, a plurality of spaced openings extending between the top and bottom surfaces, and a recess formed in the bottom surface. The spacing between the spaced openings matches the spacing between the spaced spray nozzles. The protective cover has a height that is greater than or equal to the height of the spaced spray nozzles, and the protective cover has side walls that slope downwardly and outwardly between the top and bottom surfaces of the protective cover.

Abstract: The present invention is intended to provide a vehicular attached matter removing device that reduces a mechanical load on the device at lower facility and running costs and splash a vehicle with a sufficient amount of fluid at a high speed to remove efficiently attached matter such as dirt and rainwater. A tire cleaning device 1 includes cleaning tanks 2 that are filled with a cleaning liquid in which at least the ground-contact surfaces of tires T are immersed. When the vehicle passes through the cleaning tanks, the surfaces of the tires T can be cleaned by the cleaning liquid in the cleaning tanks 2. The tire cleaning device 1 is provided with pump means 11 that are pressed by the weight of the vehicle to jet the cleaning liquid in the cleaning tanks 2 onto the tires T.

Abstract: When mitigating collisions between a host vehicle and a forward vehicle, the forward vehicle is monitored and real-time data regarding distance and relative acceleration between the host and forward vehicles is used to continuously calculate a collision probability. The collision probability is used to calculate a deceleration request value sufficient to slow or stop the host vehicle within the following distance to the forward vehicle. The deceleration request value is transmitted to an antilock braking system (ABS) controller that caches the most-recently received value for execution upon receipt of an execution command. When the collision probability exceeds a first threshold, the ABS is instructed to arm the braking system. Upon detection of a brake pedal engagement, the ABS executes the brake request with the currently-cached value.

Abstract: The brake controller includes a friction brake device, a regeneration brake device, a required braking force calculating portion, a vehicle motion control portion which distributes the required braking force to the non-regeneration braking side right/left wheels that is either one of the right/left front wheels and right/left rear wheels, a maximum braking force calculating portion which calculates the maximum braking force at each wheel and a braking force control portion-which calculates the regeneration braking force generated at the regeneration braking side right/left wheels within a range where the regeneration braking force to be generated at the regeneration braking side right/left wheels does not exceed a smaller value of the maximum braking forces of the regeneration braking side right/left wheels, based on the required braking force and the distribution of the braking force to the non-regeneration braking side right/left wheels.

Abstract: A brake system does not change immediately an operating condition of a left front brake although a slipping condition is detected at the left front wheel based on a signal detected by a left detector in such a state that a slipping condition is not detected at a right front wheel based on a signal detected by a right detector, and does not change immediately an operating condition of a right front brake although a slipping condition is detected at the right front wheel based on a signal detected by the right detector in such a state a slipping condition is not detected at the left front wheel based on a signal detected by the left detector.

Abstract: A brake system includes a brake activator which reduces, when a slipping condition of a right front wheel is detected based on a signal which is detected by a right detector, both braking forces on the right front wheel and a left front wheel to a lower level than a level of a braking force which is obtained as a result of operation of an input member and which reduces, when a slipping condition of the left front wheel is detected based on a signal which is detected by a left detector, both braking forces on the left front wheel and the right front wheel to a lower level than a level of a braking force which is obtained as a result of operation of the input member.

Abstract: A retaining assembly for fixing a flange part, which is provided on a braking device, to a firewall of a motor vehicle, the firewall separating an engine chamber from a vehicle interior. A retaining plate is secured to the firewall face facing the engine chamber, and the flange part and the retaining plate are engaged with each other by both a form-fitting as well as force-fitting connection.

Abstract: A computer-implemented method for an air brake system of a train with an air brake system, including: (i) determining consist data associated with the train; (ii) determining track data comprising location data and grade data; (iii) determining required train holding force based at least partially on the consist data and the track data; and (iv) determining hand brake arrangement actuation data based at least partially on the required train holding force. An improved hand brake arrangement is also disclosed.

Abstract: The present invention discloses a booster (100) and a brake system. The booster includes a valve body (2) and a boosting assembly including a ball screw. The ball screw includes a screw rod (40), a nut (41) and a plurality of balls cooperating with and between the screw rod (40) and the nut (41). The nut (41) is linked with the valve body (2) and the nut (41) moves along a straight line on its cooperated screw rod (40) so as to drive the valve body (2) to move along a straight line. The brake system includes the booster (100) and a hydraulic system. The hydraulic system includes a braking main cylinder (11) having a piston (12), and the valve body (2) is connected to the piston (12). The booster can provide high transmission efficiency.

Abstract: A hydraulic block for a hydraulic unit of a brake controller of a hydraulic vehicle brake system is configured to fit with hydraulic components such as solenoid valves of the brake controller. The hydraulic block is manufactured by 3D printing, which enables considerably more complex line routing than manufacture by machining.

Abstract: The present disclosure provides systems and methods related to determining observed applied brake force of an aircraft braking system. In various embodiments, a system for calculating observed applied force comprises a current sensor in communication with a controller, a position sensor in communication with the controller and configured to measure a rotational speed of a motor shaft, and a tangible, non-transitory memory configured to communicate with the controller.

Abstract: Braking systems and methods having above atmospheric pressure applied to the working hydraulic fluid of the braking system. In certain preferred arrangements, the braking system includes at least one source of pressure, which pressurizes a fluid. The pressurized fluid acts on respective pressure surfaces of the master plunger(s) and the slave piston(s) that are opposite the active or working surfaces of the master plunger(s) and the slave piston(s).

Abstract: A vernier calliper for measuring the thickness of a disc brake rotor fitted to a vehicle, the vernier calliper including: (i) first and second members which are mounted for sliding movement relative to one another along an axis; (ii) first and second abutments located on the first and second members respectively and being adapted, in use, to engage first and second sides of a disc brake rotor, the first abutment including an abutment surface; (iii) retaining means for retaining the calliper in an operative position in which: (iv) the first abutment surface engages the first side of the disc and is parallel thereof; (v) the second abutment engages the second side of the disc; and (vi) said axis is orthogonal to said first and second sides of the disc.

Abstract: A brake control method for a hybrid electric vehicle including a control mode of a first interval to control regenerative brake of a motor may include sensing, by an Electronic Stability Control system controller (ESC ECU), a time when a wheel brake pressure detected by a pressure sensor of a wheel brake is ‘0’ after entering a control mode of a second interval, determining, by the ESC ECU, a pedal stroke in which the wheel brake pressure is ‘0’ from a ‘pedal stroke Vs wheel brake pressure’ map, changing and setting, by the ESC ECU, the pedal stroke in which the wheel brake pressure is ‘0’ to an upper threshold stroke value of a ‘pedal stroke Vs pressure’ map, and re-entering the control mode of the first interval, when the pedal stroke depending on the brake pedal operation decreases to the changed upper threshold stroke value or less.

Abstract: In a case where external electricity feed is being performed, a water temperature threshold Tref is set to a temperature T2 that is lower than in a case where the external electricity feed is not being performed, and canister puree is executed when an engine is in operation and a cooling water temperature Tw is the water temperature threshold Tref or higher. Thereby, it is possible to increase the opportunity to perform the canister purge, and to enhance evaporative emission performance. Furthermore, in the case where the external electricity feed is being performed, a maximum purge rate Pmax is set to a value P2 that is greater than in the case where the external electricity feed is not being performed. Thereby, it is possible to quickly complete the canister purge.

Abstract: A controlling system for a hybrid vehicle, the controlling system including an engine configured to stop running when the vehicle stops; a motor configured to provide a driving power to the vehicle, wherein the motor is supplied with electric power through a battery; a traffic information receiver configured to receive traffic information; and a processor configured to control the engine or the motor, or both, based on the traffic information.

Abstract: The present disclosure provides a hybrid electric vehicle, a drive control method and a drive control device of a hybrid electric vehicle. The drive control method includes: obtaining a current gear position of the hybrid electric vehicle and a current electric charge level of a power battery; obtaining a slope of a road on which the hybrid electric vehicle is driving, if the current gear position of the hybrid electric vehicle and the current electric charge level of the power battery meet a preset requirement; and causing a working state of an engine and/or a motor of the hybrid electric vehicle according to the slope of the road on which the hybrid electric vehicle is driving.

Abstract: A control strategy is provided for a hybrid vehicle that will increase drivability during low or decreasing driver demands. Coordination between shifting the transmission and stopping or (non-demand) starting of the engine can increase drivability. The vehicle includes a motor/generator with one side selectively coupled to the engine and another side selectively coupled to the transmission. The control strategy acts when an engine start or stop is requested while driver demand is decreasing and a shift of the transmission is demanded. To inhibit these events from proceeding simultaneously, the control strategy delays the engine from starting or stopping until the transmission has finished shifting, or vice versa.

Abstract: A hybrid vehicle includes a traction battery, an internal combustion engine, an electric machine configured to provide torque assistance to the engine, and a controller or a powertrain control system having a controller. The controller is programmed to respond to a percentage of state of charge (SOC) allocated for torque assistance. An allocation for torque assistance is a change in SOC of the battery attributed to a current flow to the electric machine for torque assistance. When the change in SOC attributed to the current flow is greater than a predetermined change, the controller will halt the current flow to the electric machine to cease torque assistance.

Abstract: A hybrid vehicle includes a traction battery having a battery fan, an engine, an electric machine coupled to the battery, and a controller or at least one powertrain module having a controller. The controller is programmed to respond to a change in a user selected powertrain operating mode to a performance mode. This change may occur while a pedal demand is generally constant. The controller may increase an available power of the battery to drive the electric machine without altering state of charge operating limits of the battery. The increase in available power of the battery may include increasing a state of charge of the battery or reducing the battery temperature such that a current may flow from the battery for a longer time period. Also, the overall available power for the vehicle may include operation of the engine at a higher rotational speed.

Abstract: A DC/DC converter is driven when an inter-terminal voltage of a low-voltage battery is lower than a determination voltage and an engine is started when the inter-terminal voltage becomes lower than a determination voltage during the driving of the DC/DC converter so that an alternator is driven at a predetermined driving point at which the alternator can he efficiently driven and the DC/DC converter is controlled such that the inter-terminal voltage of the low-voltage battery becomes a rated voltage. Energy efficiency can be improved since the alternator is efficiently driven.

Abstract: The present disclosure provides a hybrid electric vehicle, a drive control method and a drive control device of a hybrid electric vehicle. The drive control method includes: obtaining a current gear position and a current operating mode of the hybrid electric vehicle, a current electric charge level of a power battery and a slope of a road on which the hybrid electric vehicle is driving; determining whether the hybrid electric vehicle is within a taxiing start-stop interval according to the current gear position of the hybrid electric vehicle, the current electric charge level of the power battery, and the slope of the road; if the hybrid electric vehicle is within the taxiing start-stop interval, obtaining a current speed of the hybrid electric vehicle; and causing the hybrid electric vehicle to enter a small load stop mode or a small load stall mode according to the current speed.

Abstract: The present disclosure provides a drive control method and a drive control device of a hybrid electric vehicle. The method includes: obtaining a current gear position of the vehicle, a current electric charge level of a power battery and a slope of a road on which the vehicle is driving; determining whether the vehicle is within a taxiing start-stop interval according to the current gear position, the current electric charge level, and the slope; if the vehicle is within the taxiing start-stop interval, obtaining a current speed of the vehicle; if the current speed is greater than or equal to a first speed threshold, and less than a second speed threshold, causing the vehicle to enter a small load stop mode; and if the current speed is greater than or equal to the second speed threshold, and less than a third speed threshold, causing the vehicle to enter a small load stall mode.

Abstract: The present disclosure provides a drive control method, a drive control device of a hybrid electric vehicle and a hybrid electric vehicle. The drive control method includes: obtaining a current gear position of the hybrid electric vehicle, a current electric charge level of a power battery and a slope of a road on which the hybrid electric vehicle is driving; obtaining a current speed of the hybrid electric vehicle if the current gear position of the hybrid vehicle, the current electric charge level of the power battery, and the slope of the road on which the hybrid electric vehicle is driving meet a preset requirement; and causing the hybrid electric vehicle to enter a small load stop mode if the current speed is greater than or equal to a first speed threshold, and less than a second speed threshold.

Abstract: The present disclosure provides a hybrid electric vehicle, a drive control method and a drive control device of a hybrid electric vehicle. The drive control method includes: obtaining a current gear position and a current operating mode of the hybrid electric vehicle, a current electric charge level of a power battery and a slope of a road where the hybrid electric vehicle is; determining whether the hybrid electric vehicle is within a taxiing start-stop interval according to the current gear position of the hybrid electric vehicle, the current electric charge level of the power battery, and the slope of the road; if the hybrid electric vehicle is within the taxiing start-stop interval, further obtaining a current speed of the hybrid electric vehicle; and causing the hybrid electric vehicle to enter a small load stop mode or a small load stall mode according to the current speed.

Abstract: The present disclosure provides a hybrid electric vehicle, a drive control method and a drive control device of a hybrid electric vehicle. The drive control method includes: obtaining a current gear position of the hybrid electric vehicle and a current electric charge level of a power battery; determining whether the vehicle is within a speed start-stop interval according to the current gear position of the hybrid electric vehicle and the current electric charge level of the power battery; obtaining a slope of a road on which the vehicle is driving and a current speed of the hybrid electric vehicle, if the vehicle is within a speed start-stop interval; and controlling a working state of an engine and/or a motor of the hybrid electric vehicle according to the slope of the road on which the vehicle is driving and the current speed of the vehicle.

Abstract: A vehicle and a method of controlling a vehicle are provided. The vehicle may include a controller programmed to, in response to a change from a first to a second powertrain operating mode, operate an engine and electric machine to increase a state of charge target of a traction battery to increase propulsion torque available from the electric machine. The controller may be further programmed to, in response to a decrease in accelerator pedal position and a vehicle speed being less than a threshold speed while operating the powertrain in the second powertrain operating mode and the engine and electric machine are coupled via a friction element, decrease a pressure of the friction element to a first target pressure to decouple the engine from the electric machine.

Abstract: A control system for hybrid vehicles that ensures high motor power while limiting damage on a planetary gear unit is provided. In a planetary gear unit, a sun gear is connected to a first motor, a ring gear is connected to a second motor, and a carrier is connected to an engine. An operating mode of the hybrid vehicle can be selected from a hybrid mode, a single-motor mode, and a dual-motor mode. The control system is configured to shift the operating mode to the hybrid mode if an estimated temperature of the pinion gear is higher than a threshold temperature (step S5), and to the single-motor mode if the estimated temperature of the pinion gear is lower than a threshold temperature (step S7).

Abstract: A hybrid vehicle travels by a driving force of either one or both of an engine and an electric motor. The hybrid vehicle includes a traveling mode switching module that switches among a plurality of traveling modes including a motor traveling mode in which the vehicle travels by the motor prior to the engine and an engine and motor combined traveling mode in which the vehicle travels using both the motor and the engine, and a condition determining module that determines whether a bad road condition defined in advance is met. If it is determined that the bad road condition is met, the traveling mode switching module causes the engine to start regardless of the traveling mode at the time when the engine is stopped, and prohibits a stop of the engine while the bad road condition is met.

Abstract: A drive system for a hybrid vehicle includes an engine, a motor, a rotary shaft, an engine disconnect clutch, a motor disconnect clutch, an automatic transmission, and an electronic control unit. The electronic control unit is configured to, while either one of an engagement control and a rotation change control is being executed, when a request to execute the other one of the engagement control and the rotation change control has been issued, (a) delay a start timing of the other one of the engagement control and the rotation change control until execution of the one of the engagement control and the rotation change control is completed, and then (b) start execution of the other one of the engagement control and the rotation change control after execution of the one of the engagement control and the rotation change control has been completed.

Abstract: An electronic control unit included in a hybrid vehicle is configured to switch between first limp home travel control and second limp home travel control based on a first temperature difference, a second temperature difference, and a state of charge when abnormality occurs to a cooler. The first temperature difference is a value that is obtained by subtracting an element temperature of a first inverter from a first load rate limit temperature at which load rate limitation is applied to a first motor. The second temperature difference is a value that is obtained by subtracting an element temperature of a second inverter from a second load rate limit temperature at which the load rate limitation is applied to a second motor.

Abstract: In the case where a throttle valve has a sticking abnormality, a hybrid vehicle performs failsafe operation (limp home mode) with fixing the throttle valve to an opener position (S100) and sets a restoration diagnosis cooling water temperature T1 such as to decrease with a decrease in state of charge SOC of a battery (S120). When cooling water temperature Tw of the engine becomes equal to or higher than the restoration diagnosis cooling water temperature T1, the hybrid vehicle performs sticking restoration diagnosis to determine whether the throttle valve is restored from the sticking abnormality (S150). This allows for earlier diagnosis of whether the throttle valve is restored from the sticking abnormality at the lower state of charge SOC of the battery and enables the hybrid vehicle to return to normal operation at an earlier time. As a result, this ensures the more adequate sticking restoration diagnosis.

Abstract: The disclosure includes a method for autocompleting an in-vehicle operation that includes monitoring sensors for sensor data. The method includes determining an occurrence of an initial vehicle operation performed by a user based on the sensor data. The method includes determining a vehicle task from a digitally stored dataset based on the initial vehicle operation. The method includes determining a next vehicle operation to autocomplete based on the vehicle task. The method includes autocompleting the next vehicle operation. The method includes determining whether the vehicle task is complete.

Abstract: An arrangement for damping a possible pitching oscillation of a working vehicle supported on the ground by elastic elements is equipped with means to detect an expected and/or existing pitching oscillation of the working vehicle, and a control device, which is connected to the means and to an actuator to influence the propulsion rate of the working vehicle and which can be operated to control the actuator so as to damp the pitching oscillation.

Abstract: A speed change control apparatus for a work vehicle includes a hydraulic continuously variable speed transmission that performs speed change on power input from an engine by changing a trunnion shaft angle based on a depressing amount of a speed change pedal and outputs the power, a pedal position detector that detects a pedal position responsive to the depressing amount of the speed change pedal, and a control unit that controls a number of revolutions of the engine and the trunnion shaft angle of the hydraulic continuously variable speed transmission based on a detection value of the pedal position detector. The control unit performs control so that the trunnion shaft angle is maximized at a second pedal position set to a position shallower than a first pedal position at which the number of revolutions of the engine is maximized by a depressing operation of the speed change pedal.